Flexible waveguide having an asymmetric optical-loss performance curve and improved worst-case optical-loss performance

ABSTRACT

Embodiments of the invention are directed a waveguide having a first waveguide segment that includes a set of first waveguide segment confinement parameters; a second waveguide segment having routing bends and a set of second waveguide segment confinement parameters; and a third waveguide segment having a set of third waveguide segment confinement parameters. The waveguide is configured to guide optical data according to an asymmetric optical-loss performance curve that is a plot of the sets of first, second, and third waveguide segment confinement parameters on a first axis; and a level of optical-loss performance that results from the sets of first, second, and third waveguide segment confinement parameters on a second axis. The sets of first, second, and third waveguide segment confinement parameters are configured to, collectively, maximize a predetermined worst-case optical-loss performance level of the asymmetric optical-loss performance curve within a range of waveguide fabrication tolerances.

DOMESTIC PRIORITY

This application is a divisional of U.S. patent application Ser. No.16/433,005, filed Jun. 6, 2019, the disclosure of which is incorporatedby reference herein in its entirety.

BACKGROUND

The present invention relates in general to data transmission systems.More specifically, the present invention relates to fabrication methodsand resulting structures for a flexible waveguide having an asymmetricoptical-loss performance curve and novel confinement parameters that areconfigured to improve the flexible waveguide's worst-case optical-lossperformance within fabrication tolerances.

Integrated circuits (ICs) are typically formed from various circuitconfigurations of semiconductor-based devices formed on semiconductorwafers. Semiconductor-based devices are formed on semiconductor wafersby depositing many types of thin films of material over thesemiconductor wafers, patterning the thin films of material, dopingselective regions of the semiconductor wafers, etc. After completion ofdevice level and interconnect level fabrication processes, thesemiconductor devices on the wafer are separated and the final productsis packaged.

The terms “interconnect bottleneck” describe limitations on theperformance of data processing systems that result from interconnectlimitations rather than IC performance. The electrons that transmitelectronic data are sluggish and interact with one another and the ICcopper wires through which they travel, thus limiting how muchinformation electronic IC components can transmit. Interconnectbottlenecks are mitigated, and in many cases overcome, by replacingselected IO electronic data and metallic connections on ICs withphoton-based optical data, waveguide transmission lines, and opticalcouplers. In contrast to the electrons that carry electronic data, thephotons that carry optical data move at light speed with nointerference, thus allowing many discrete pieces of information to betransmitted at once.

An IC having electro-optical components that can receive and processoptical data is known generally as a photonic IC. Optical IO datareceived at a photonic IC are routed to target downstream optoelectroniccomponents, as well as output optical fibers. Photonic ICs can befabricated using processes similar to the previously described processesused to fabricate electronic ICs, which makes it possible to producephotonic ICs efficiently and at scale.

In general, an optical waveguide can be any structure that acts as a“light pipe” that confines and guides light. Optical waveguides can beimplemented as dielectric structures that transmit various forms ofradiation or electromagnetic waves in a direction along the waveguide'spropagation axis. Optical waveguides are fundamental building blocks ofmany optical systems, including fiber-optic communications links; fiberlasers and amplifiers for high-power applications; and all-opticalphotonic ICs.

SUMMARY

Embodiments of the invention are directed an optical waveguide structurehaving waveguide dimensions that are within a range of fabricationtolerances. A non-limiting example of the optical waveguide structureincludes a multi-segmented optical waveguide having a first waveguidesegment that includes a set of first waveguide segment confinementparameters; a second waveguide segment communicatively coupled to thefirst waveguide segment and configured to route optical data through arouting path having bends, the second waveguide segment having a set ofsecond waveguide segment confinement parameters; and a third waveguidesegment communicatively coupled to the second waveguide segment andhaving a set of third waveguide segment confinement parameters. Themulti-segmented optical waveguide is configured to confine and guideoptical data according to an asymmetric optical-loss performance curvethat is substantially asymmetrical with respect to a peak optical-lossperformance level of the asymmetric optical-loss performance curve. Theasymmetric optical-loss performance curve is a plot of the set of firstwaveguide segment confinement parameters, the set of second waveguidesegment confinement parameters, and the set of third waveguide segmentconfinement parameters on a first axis; and a level of optical-lossperformance that results from the set of first waveguide segmentconfinement parameters, the set of second waveguide segment confinementparameters, and the set of third waveguide segment confinementparameters on a second axis. The set of first waveguide segmentconfinement parameters, the set of second waveguide segment confinementparameters, and the set of third waveguide segment confinementparameters are configured to, collectively, maximize a predeterminedworst-case optical-loss performance level of the asymmetric optical-lossperformance curve within the range of fabrication tolerances.

Embodiments of the invention are directed an optical waveguide structurehaving waveguide dimensions that are within a range of fabricationtolerances. A non-limiting example of the optical waveguide structureincludes a multi-segmented optical waveguide having a first waveguidesegment that includes a set of first waveguide segment confinementparameters; a second waveguide segment communicatively coupled to thefirst waveguide segment and configured to route optical data through arouting path having bends, the second waveguide segment having a set ofsecond waveguide segment confinement parameters; and a third waveguidesegment communicatively coupled to the second waveguide segment andhaving a set of third waveguide segment confinement parameters. Themulti-segmented optical waveguide is configured to confine and guideoptical data according to an asymmetric optical-loss performance curvethat is substantially asymmetrical with respect to a peak optical-lossperformance level of the asymmetric optical-loss performance curve. Theasymmetric optical-loss performance curve is a plot of the set of firstwaveguide segment confinement parameters, the set of second waveguidesegment confinement parameters, and the set of third waveguide segmentconfinement parameters on a first axis; and a level of optical-lossperformance that results from the set of first waveguide segmentconfinement parameters, the set of second waveguide segment confinementparameters, and the set of third waveguide segment confinementparameters on a second axis. The set of first waveguide segmentconfinement parameters, the set of second waveguide segment confinementparameters, and the set of third waveguide segment confinementparameters are each determined based at least in part on the range offabrication tolerances. The set of first waveguide segment confinementparameters, the set of second waveguide segment confinement parameters,and the set of third waveguide segment confinement parameters arefurther configured to, collectively, provide the asymmetric optical-lossperformance curve with a predetermined worst-case optical-lossperformance level within the range of fabrication tolerances.

Embodiments of the invention are directed to an optical coupling system.A non-limiting example of the optical coupling system includes anoptical fiber communicatively coupled to a flexible waveguide structureand a photonic integrated circuit communicatively coupled to theflexible waveguide structure that includes a multi-segmented opticalwaveguide that includes a first waveguide segment having a set of firstwaveguide segment confinement parameters; a second waveguide segmentcommunicatively coupled to the first waveguide segment and configured toroute optical data through a routing path having bends, the secondwaveguide segment having a set of second waveguide segment confinementparameters; and a third waveguide segment communicatively coupled to thesecond waveguide segment and having a set of third waveguide segmentconfinement parameters. The multi-segmented optical waveguide isconfigured to guide optical data according to an asymmetric optical-lossperformance curve that is substantially asymmetrical with respect to apeak optical-loss performance level of the asymmetric optical-lossperformance curve. The asymmetric optical-loss performance curve is aplot of the set of first waveguide segment confinement parameters, theset of second waveguide segment confinement parameters, and the set ofthird waveguide segment confinement parameters on a first axis; and alevel of optical-loss performance that results from the set of firstwaveguide segment confinement parameters, the set of second waveguidesegment confinement parameters, and the set of third waveguide segmentconfinement parameters on a second axis. The set of first waveguidesegment confinement parameters, the set of second waveguide segmentconfinement parameters, and the set of third waveguide segmentconfinement parameters are configured to, collectively, maximize aworst-case optical-loss performance of the asymmetric optical-lossperformance curve within the range of fabrication tolerances.

Embodiments of the invention are directed to a method of using aflexible waveguide having waveguide dimensions that are within a rangeof fabrication tolerances. A non-limiting example of the method includesusing the flexible waveguide to couple optical signals in a firstdirection from an optical fiber to a photonic integrated circuit; andusing the flexible waveguide to couple optical signals in a seconddirection from the photonic integrated circuit to the optical fiber. Theflexible waveguide includes a multi-segmented optical waveguide thatincludes a first waveguide segment having a set of first waveguidesegment confinement parameters; a second waveguide segmentcommunicatively coupled to the first waveguide segment and configured toroute optical data through a routing path having bends, the secondwaveguide segment having a set of second waveguide segment confinementparameters; and a third waveguide segment communicatively coupled to thesecond waveguide segment and having a set of third waveguide segmentconfinement parameters. The multi-segmented optical waveguide isconfigured to guide optical data according to an asymmetric optical-lossperformance curve that is substantially asymmetrical with respect to apeak optical-loss performance level of the asymmetric optical-lossperformance curve. The asymmetric optical-loss performance curve is aplot of the set of first waveguide segment confinement parameters, theset of second waveguide segment confinement parameters, and the set ofthird waveguide segment confinement parameters on a first axis; and alevel of optical-loss performance that results from the set of firstwaveguide segment confinement parameters, the set of second waveguidesegment confinement parameters, and the set of third waveguide segmentconfinement parameters on a second axis. The set of first waveguidesegment confinement parameters, the set of second waveguide segmentconfinement parameters, and the set of third waveguide segmentconfinement parameters are configured to, collectively, maximize apredetermined worst-case optical-loss performance level of theasymmetric optical-loss performance curve within the range offabrication tolerances.

Additional features and advantages are realized through the techniquesdescribed herein. Other embodiments and aspects are described in detailherein. For a better understanding, refer to the description and to thedrawings.

BRIEF DESCRIPTION OF THE DRAWINGS

The subject matter which is regarded as the present invention isparticularly pointed out and distinctly claimed in the claims at theconclusion of the specification. The foregoing and other features andadvantages are apparent from the following detailed description taken inconjunction with the accompanying drawings in which:

FIG. 1A depicts a plot illustrating a known waveguide design approach;

FIG. 1B depicts a plot and a diagram illustrating a discovery inaccordance with aspects of the invention;

FIG. 2 depicts optical-loss maps and a diagram further illustrating adiscovery in accordance with aspects of the invention;

FIG. 3A depicts optical-loss plots that compare results of the knownwaveguide design approach shown in FIG. 1B with results of a novelwaveguide design approach in accordance with aspects of the invention;

FIG. 3B depicts optical-loss maps that further compare results of theknown waveguide design approach shown in FIG. 1B with results of thenovel waveguide design approach in accordance with aspects of theinvention;

FIG. 4A depicts a top-down view of an optical coupling system accordingto embodiments of the invention;

FIG. 4B depicts a side-view of the optical coupling system shown in FIG.4A;

FIG. 5A depicts a computer-based optical simulation and design (OSD)system configured to implement aspects of the invention;

FIG. 5B depicts additional details of how a computer system of the (OSD)system shown in FIG. 5A can be implemented;

FIG. 6 depicts a method of determining the confinement parameters of theFP-WG shown in FIGS. 4A, 4B and 8 using a novel waveguide designapproach according to embodiments of the invention;

FIG. 7 depicts a combined optical-loss map illustrating aspects of themethod shown in FIG. 6;

FIG. 8 depicts a cross-sectional view of the FP-WG shown in FIGS. 4A and4B, taken along lines A-A, B-B, or C-C shown in FIG. 4A;

FIG. 9 depicts a table showing confinement parameters and ranges ofconfinement parameters of the cross-sectional view of the FP-WG shown inFIG. 8, taken along line A-A of the FP-WG shown in FIG. 4A, wherein theconfinement parameters and ranges of confinement parameters aredetermined in accordance with the method shown in FIG. 6;

FIG. 10 depicts a table showing confinement parameters and ranges ofconfinement parameters of the cross-sectional view of the FP-WG shown inFIG. 8, taken along line B-B of the FP-WG shown in FIG. 4A, wherein theconfinement parameters and ranges of confinement parameters aredetermined in accordance with the method shown in FIG. 6; and

FIG. 11 depicts a table showing confinement parameters and ranges ofconfinement parameters of the cross-sectional view of the FP-WG shown inFIG. 8, taken along line C-C of the FP-WG shown in FIG. 4A, wherein theconfinement parameters and ranges of confinement parameters aredetermined in accordance with the method shown in FIG. 6.

The diagrams depicted herein are illustrative. There can be manyvariations to the diagram or the operations described therein withoutdeparting from the spirit of the invention. For instance, the actionscan be performed in a differing order or actions can be added, deletedor modified. Also, the term “coupled” and variations thereof describeshaving a communications path between two elements and does not imply adirect connection between the elements with no interveningelements/connections between them. All of these variations areconsidered a part of the specification.

In the accompanying figures and following detailed description of thedescribed embodiments, the various elements illustrated in the figuresare provided with two- or three-digit reference numbers. With minorexceptions, the leftmost digit(s) of each reference number correspond tothe figure in which its element is first illustrated.

DETAILED DESCRIPTION

It is understood in advance that, although this description includes adetailed description of a particular flexible waveguide architecture,implementation of the teachings recited herein are not necessarilylimited to a particular flexible waveguide architecture. Ratherembodiments of the present invention are capable of being implemented inconjunction with any other type of flexible waveguide architecture, nowknown or later developed, as long as the flexible waveguide architecturecan incorporate the novel waveguide fabrication operations, resultingwaveguide structures, and methods of use described herein.

For the sake of brevity, conventional techniques related tosemiconductor device and integrated circuit (IC) fabrication may or maynot be described in detail herein. Moreover, the various tasks andprocess steps described herein can be incorporated into a morecomprehensive procedure or process having additional steps orfunctionality not described in detail herein. In particular, varioussteps in the manufacture of semiconductor devices andsemiconductor-based ICs are well known and so, in the interest ofbrevity, many conventional steps will only be mentioned briefly hereinor will be omitted entirely without providing the well-known processdetails.

Turning now to an overview of technologies that are relevant to aspectsof the invention, as previously described herein, interconnectbottlenecks are mitigated, and in many cases overcome, by replacingselected electrical data transmission and metallic connections withoptical data transmission and optics-based structures for carrying theoptical data to target downstream photonic and optoelectroniccomponents. Optical loss, which can be measured in decibels (dB), is alimiting factor in the effective and efficient implementation of opticaldata transmission systems and downstream optical routing systems.

FIG. 1A depicts an optical-loss plot 100A that results from a knownwaveguide design approach that selects and defines the waveguideconfinement parameters in a manner that maximizes the peak optical-lossperformance of the waveguide-under-design within the waveguide'sfabrication tolerance window 103A. For ease of reference, this generaltype of waveguide design approach will be referred to herein as a“maximize peak optical-loss performance” (MPOLP) waveguide designapproach. The optical-loss plot 100A plots on the y-axis theoptical-loss performance of the waveguide-under-design, and plots on thex-axis the level of optical confinement within thewaveguide-under-design based on various waveguide confinementparameters. In general, a smaller optical-loss performance valuerepresents a relatively larger optical loss, and a larger optical-lossperformance value represents a relatively smaller optical loss. Anoptical waveguide's ability to guide and confine optical signals can beclassified according to a variety of so-called “confinement parameters,”which can include any waveguide feature/parameter that impacts thewaveguide's ability to guide and confine optical signals, including forexample, the waveguide's geometry (e.g., planar, slab/strip, fiberwaveguides, etc.), refractive index, refractive index distribution(e.g., step, gradient, etc.), guiding mechanism (e.g., total internalreflection, anti-guiding, photonic band-gap, etc.), material (e.g.,glass, polymer, semiconductor, etc.), and the like. Electromagneticfield distributions that are invariant with propagation, when timeaveraged, are known as modes. Modes can have an associated polarizationof light, which is, in general, a dominant orientation of the electricfield of light. For high-speed data transmission, it may or may not bepreferred to use so-called single-mode waveguides, which are waveguidesthat can only propagate one mode of each polarization. Waveguides thatcan sustain additional modes are called multimode waveguides.

In the MPOLP waveguide design approach depicted in FIG. 1A, once theconfinement parameters have been defined for maximum peak optical-lossperformance, the tolerance penalty of the defined confinement parametersis calculated. Accordingly, while MPOLP waveguide design approaches canmaximize peak optical-loss performance, the resulting waveguide designis susceptible to significant fabrication tolerance penalties(worst-case optical-loss performance level shown in FIG. 1A) within thefabrication tolerance window 103A.

The shape of the optical-loss curve 102A is generally expected to besymmetrical around the peak optical-loss performance of the optical-losscurve 102A. This is not only generally true with respect to the functionof confinement parameters but also with respect to the function of otherparameters such as alignment of components or resonant frequencies ofresonators. Although the symmetrical shape of the optical-loss curve102A is accurate for many structures, aspects of the invention(described in greater detail subsequently herein) rest on and leverage anon-obvious discovery that the symmetrical shape of the optical-losscurve 102A is not accurate when the waveguide-under-design is alow-confinement waveguide in which at least some of the low-confinementwaveguide's confinement parameters have a strongly non-linearrelationship with the waveguide's level of confinement. An example ofsuch a low-confinement waveguide is a flexible polymer waveguide (FP-WG)120 shown in cross-section in FIG. 1B.

FIG. 1B depicts an optical-loss plot 100B and the cross-sectional viewof the FP-WG 120. The optical-loss plot 102B illustrates theabove-described discovery in accordance with aspects of the inventionthat the optical-loss curve 102B and its associated worst-caseoptical-loss performance are asymmetrical within the fabricationtolerance window 103B of the FP-WG 120. As shown in FIG. 1B, the FP-WG120 includes a core 122 and a cladding 124 having a lower claddingregion 124A and an upper cladding region 124B. Examples of FP-WG designparameters that affect waveguide confinement in a non-liner way includethe height and width of the waveguide core 122, the index contrastbetween the core 122 and the cladding 124, and the index contrastbetween the lower cladding 124A and the upper cladding 124B. Morespecifically, higher width/height/index-contrast values in the FP-WG 120provide higher confinement, while asymmetry between the refractive indexof the lower cladding region 124A and the refractive index of the uppercladding region 124B reduces confinement.

Similar to the symmetrical optical-loss curve 102A shown in FIG. 1A, theMPOLP waveguide design approach was used to define the confinementparameters of the waveguide associated with the asymmetricaloptical-loss curve 102B shown in FIG. 1B. When the MPOLP design approachis used in an optical structure with notably asymmetric optical lossperformance as a function of the structure's design parameters, theresulting FP-WG design is susceptible to relatively large tolerancepenalties (worst-case optical-loss performance level shown in FIG. 1B)within the expected window of fabrication tolerances 103B.

FIG. 2 depicts optimization maps 104A-104D and a cross-sectional view ofthe FP-WG 120, all of which illustrate that the fabrication tolerancepenalty that results from applying the MPOLP design approach to thelow-confinement FP-WG 120 is severe. In general, the points on theoptical-loss curve 102B can be taken from the optimization maps104A-104D. More specifically, the MPOLP design approach was applied tofind the core width that maximizes the transmission between an opticalfiber and an FP-WG (e.g., the FP-WG 120). This was done for a set ofcore height and index contrasts. Each point on maps 104A-104D shows theoptical loss at such transition when various fabrication tolerances areapplied. This is for the full set of core height, index contrast, andMPOLP obtained width. The maps 104A-140D can be created using knownoptical simulation software (e.g., optical simulator 514 shown in FIG.5A) controlled by known mathematical control software (e.g.,mathematical computing and control module 512 shown in FIG. 5A) to plotthe expected optical-loss performance against a selected criterion fordifferent values of a particular confinement parameter at differentlocations in the fabrication tolerance window 103B (shown in FIG. 1B).For the example depicted in FIG. 2, the criterion is maximizing peakoptical-loss performance, and the confinement parameter is the indexcontrast of the core 122 of the FP-WG 120. Thus, each map 104A-104Ddepicts the impact of different index contrast values of the core 122 onpeak optical-loss performance. A point on the right side of theoptical-loss curve 102B would be taken from the map 104A, and points onthe left side of the optical-loss curve 102B would be taken from themaps 104B-104D. Thus, the maps 104A-104D show examples of worst-caseoptical-loss in optical fiber to FP-WG 120 coupling when thelow-confinement FP-WG 120 is designed to maximize the peak optical-lossperformance of the optical-loss performance curve 102B.

Turning now to an overview of aspects of the invention, embodiments ofthe invention address the above-described shortcomings of the prior artby providing a low-confinement flexible waveguide with confinementparameters that have been configured and arrange to maximize aworst-case optical-loss performance of the low-confinement flexiblewaveguide within the waveguide's fabrication tolerance window. Inaccordance with aspects of the invention, the low-confinement flexiblewaveguide confinement parameters appreciate and take into account theasymmetric impact that the low-confinement waveguide confinementparameters have on optical-loss performance and worst-case optical-lossperformance in that the low-confinement flexible waveguide confinementparameters do not attempt to maximize, and do not consider, the impactthat the selected and defined confinement parameters have on peakoptical-loss performance of the low-confinement flexible waveguide. Insome aspects of the invention, the low-confinement flexible waveguideconfinement parameters are defined based at least in part on fabricationtolerances of the flexible waveguide, and based at least in part onminimizing the impact that the fabrication tolerances have on theworst-case optical-loss performance of the flexible waveguide. Hence,flexible waveguides having confinement parameters in accordance withaspects of the invention are robust to variations in fabricationtolerances in that the novel confinement parameters make the flexiblewaveguide less susceptible to variations in the worst-case optical-lossperformance of the flexible waveguide over a range of fabricationtolerances.

In some aspects of the invention, the novel flexible waveguideconfinement parameters are further configured to enable thelow-confinement flexible waveguide to be fabricated using knownlayer-by-layer planar fabrication techniques. More specifically, aspectsof the invention place fabrication constraints on selected ones of theflexible waveguide confinement parameters to enable the flexiblewaveguide to be fabricated using know layer-by-layer planar fabricationtechniques. For example, in some aspects of the invention, knownlayer-by-layer planar fabrication operations are used to fabricate theflexible waveguide, and these layer-by-layer planar fabricationoperations dictate that the flexible waveguide has a substantiallyuniform height, cladding refractive index, and core refractive indexthroughout the length of the flexible waveguide. Hence, in some aspectsof the invention, the height, cladding refractive index, and corerefractive index of the flexible waveguide are defined to maximize theworst-case optical-loss performance of the flexible waveguide while alsoremaining substantially uniform throughout the length of the flexiblewaveguide to enable the layer-by-layer planar fabrication of theflexible waveguide. Additionally, in accordance with aspects of theinvention, the fabrication constraints placed on the flexible waveguideconfinement parameters can include fabrication capabilities that limitthe flexible waveguide confinement parameters to a predetermined minimumfeature size, which can, for example, set the minimum width of theflexible waveguide. Hence, in some aspects of the invention, the widthof the flexible waveguide is defined to maximize the worst-caseoptical-loss performance of the flexible waveguide while alsomaintaining a minimum width dictated by the minimum feature sizeconstraints of the relevant layer-by-layer planar fabrication processesused to form the flexible waveguide.

In some aspects of the invention, a low-confinement flexible waveguidehaving novel flexible waveguide confinement parameters in accordancewith embodiments of the invention is a multi-segmented flexiblewaveguide, wherein each waveguide segment has novel segment confinementparameters that “globally” maximize a worst-case optical-lossperformance of all the segments of the flexible waveguide within thewaveguide's fabrication tolerance window while also taking into accountoptical-loss characteristics that are unique to the particular waveguidesegment. For example, in some embodiments of the invention, themulti-segmented waveguide includes a first waveguide segment configuredto communicatively couple to an optical fiber; a second waveguidesegment communicatively coupled to the first waveguide segment andconfigured to include bends for routing the second waveguide segmentthrough a predetermined path; and a third waveguide segmentcommunicatively coupled to the second waveguide segment and configuredto communicatively couple to a photonic IC. In the first waveguidesegment, the optical-loss characteristics that are unique to the firstwaveguide segment include optical-loss characteristics associated withcoupling a relatively large optical fiber mode (e.g., about 10 micronswide) to the first waveguide segment. In the second waveguide segment,the optical-loss characteristics that are unique to the second waveguidesegment include optical-loss characteristics associated with bends inthe second waveguide segment that result from routing the secondwaveguide segment through a predetermined path. In the third waveguidesegment, the optical-loss characteristics that are unique to the thirdwaveguide segment include optical-loss characteristics associated withcoupling the third waveguide segment to the photonic IC.

In accordance with aspects of the invention, each set of novel waveguidesegment confinement parameters does not attempt to maximize, and doesnot consider, the impact that the set of novel waveguide segmentconfinement parameters has on peak optical-loss performance of themulti-segmented flexible waveguide. In some aspects of the invention,each set of novel waveguide segment confinement parameters is definedbased at least in part on fabrication tolerances of the multi-segmentedflexible waveguide, and based at least in part on minimizing the impactthat the fabrication tolerances have on the worst-case optical-lossperformance of the multi-segmented flexible waveguide. Hence,multi-segmented flexible waveguides having the novel waveguide segmentconfinement parameters in accordance with aspects of the invention arerobust to variations in fabrication tolerances in that the sets ofwaveguide confinement parameters make the multi-segmented flexiblewaveguide less susceptible to variations in the worst-case optical-lossperformance of the multi-segmented flexible waveguide over a range ofthe waveguide's fabrication tolerances.

In some aspects of the invention, the sets of novel waveguide segmentconfinement parameters are further configured to enable themulti-segmented flexible waveguide to be fabricated using knownlayer-by-layer planar fabrication techniques. More specifically, aspectsof the invention place fabrication constraints on selected ones of thesets of waveguide segment confinement parameters to enable themulti-segmented flexible waveguide to be fabricated using knowlayer-by-layer planar fabrication techniques. For example, in someaspects of the invention, the layer-by-layer planar fabricationoperations dictate that the multi-segmented flexible waveguide has asubstantially uniform height, cladding refractive index, and corerefractive index throughout the length of the multi-segmented flexiblewaveguide. Hence, in some aspects of the invention, the height, claddingrefractive index, and core refractive index of the multi-segmentedflexible waveguide are defined to maximize the worst-case optical-lossperformance of each segment of the multi-segmented flexible waveguidewhile remaining substantially uniform throughout the length of themulti-segmented flexible waveguide to improve the ability to uselayer-by-layer planar fabrication techniques to form the multi-segmentedflexible waveguide. Additionally, in accordance with aspects of theinvention, the fabrication constraints placed on the sets of waveguidesegment confinement parameters can include fabrication capabilities thatlimit the sets of waveguide segment confinement parameters topredetermined minimum feature sizes, which can set, for example, theminimum width of the multi-segmented flexible waveguide. Hence, in someaspects of the invention, the width of each segment of themulti-segmented flexible waveguide is defined to maximize the worst-caseoptical-loss performance of the waveguide segment while also maintaininga minimum width dictated by the minimum feature size constraints of therelevant layer-by-layer planar fabrication processes used to form themulti-segmented flexible waveguide.

Turning now to a more detailed description of aspects of the invention,FIG. 3A depicts the optical-loss performance plot 100B (also shown inFIG. 1B) alongside an optical-loss performance plot 300 to compareresults of the MPOLP waveguide design approach (represented by theoptical-loss plot 100B) with results of a novel waveguide designapproach in accordance with aspects of the invention (represented by theoptical-loss plot 300). The structure-under-design associated with theoptical-loss plot 300 is a FP-WG 420 (shown in FIGS. 4A and 4B). Thenovel waveguide design approach associated with the optical-loss plot300 rests on and leverages a discovery in accordance with aspects of theinvention that the optical-loss performance curve 302 of the FP-WG 420is asymmetric within the fabrication tolerance window 303, and morespecifically is asymmetric with respect to a peak optical-lossperformance level of the optical-loss performance curve 302. In aspectsof the invention, the novel waveguide design approach defines theconfinement parameters of the FP-WG 420 (tables 900, 1000, 1100 shown inFIGS. 9, 10, and 11) based at least in part on fabrication tolerances ofthe FP-WG 420. In aspects of the invention, the novel waveguide designapproach further defines the confinement parameters of the FP-WG 420 toprovide a maximized worst-case optical-loss performance (or a “best”worst-case optical-loss level) of the FP-WG 420 within the fabricationtolerance window 303. As a result, the worst-case optical-lossperformance for the optical-loss curve 302 is a substantial improvementover the worst-case optical-loss performance for the optical-loss curve102B. For ease of reference, the novel waveguide design approach inaccordance with aspects of the invention is referred to herein as a“maximize worst-case optical-loss performance” (MWC-OLP) waveguidedesign approach. For ease of reference, the novel waveguide confinementparameters that result from the MWC-OLP design approach in accordancewith aspects of the invention is referred to herein as MWC-OLP waveguideconfinement parameters.

FIG. 3B depicts optimization plots 104D, 304 that compare results of theknown MPOLP waveguide design approach shown in FIGS. 1B and 3A withresults of the novel MWC-OLP waveguide design approach in accordancewith aspects of the invention, wherein the structure-under-design is theFP-WG 420 with performance shown for section 412 (shown in FIGS. 4A and4B), wherein the novel MWC-OLP waveguide design approach defines theMWC-OLP confinement parameters of the FP-WG 420 based at least in parton fabrication tolerances of the FP-WG 420, and wherein the novelMWC-OLP waveguide design approach further defines the MWC-OLPconfinement parameters to, collectively, provide a maximized worst-caseoptical-loss performance level (or a “best” worst-case optical-losslevel) of the optical-loss curve 302 (shown in FIG. 3A) within thefabrication tolerance window 303 of the FP-WG 420. For the optimizationplot 104D, the optical-loss is about 5 dB (a generally pooroptical-loss) for a core index contrast of about 1% and a core height ofabout 2.5 microns. For the optimization plot 304, the optical-loss isabout 1.6 dB (a generally superior optical-loss performance) for a coreindex contrast of about 1% and a core height of about 2.5 microns.

Examples of how the MWC-OLP waveguide design approach is used to formthe FP-WG 420 having MWC-OLP confinement parameters will now bedescribed with reference to FIGS. 4A-11. FIG. 4A depicts a top-down viewof an optical coupling system 400 according to embodiments of theinvention, and FIG. 4B depicts a side-view of the optical couplingsystem 400 shown in FIG. 4A. Referring more specifically to the top-downview shown in FIG. 4A, the optical coupling system 400 includes anoptical fiber 410, a fiber coupler 412, the FP-WG 420, a chip coupler442, and an integrated photonic chip 440, configured and arranged asshown. The FP-WG 420 includes a fiber coupler region 412 at one end ofthe FP-WG 420 and a chip coupler region 442 at an opposite end of theFP-WG 420. The optical fiber 410 is communicatively coupled to the FP-WG420 through the fiber coupler 412 region 412, and the FP-WG 420 iscommunicatively coupled to the integrated photonic chip 440 through thechip coupler region 442. The FP-WG 420 includes a core 422 and acladding 424. In accordance with aspects of the invention, the FP-WG420, the core 422 and the cladding 424 are each multi-segmented. Themulti-segmented FP-WG 420 includes a FP-WG segment 420A (which includesthe fiber coupler region 412), a transition segment 420D, a FP-WGsegment 420B, a transition segment 420E, and a FP-WG segment 420C (whichincludes the chip coupler region 442). The transition segment 420Dtransitions the multi-segmented FP-WG 420 from the FP-WG segment 420A tothe FP-WG segment 420B. Any suitable known technique can be used to formthe transition segment 420D. Similarly, the transition segment 420Etransitions the multi-segmented FP-WG 420 from the FP-WG segment 420B tothe FP-WG segment 420C. Any suitable known technique can be used to formthe transition segment 420E. The FP-WG segment 420A includes a coresegment 422A and a cladding segment 424A. The FP-WG segment 420Bincludes a core segment 422B and a cladding segment 424B. The FP-WGsegment 420C includes a core segment 422C and a cladding segment 424C.The line A-A through the FP-WG segment 420A represents a cross-sectionalview of the FP-WG segment 420A. The line B-B through the FP-WG segment420B represents a cross-sectional view of the FP-WG segment 420B. Theline C-C through the FP-WG segment 420C represents a cross-sectionalview of the FP-WG segment 420C. The line A-A, line B-B, and line C-Ccross-sectional views are shown collectively by the genericcross-sectional view of the FP-WG 420 shown in FIG. 8 (describedsubsequently herein).

The optical fiber(s) 410 of the illustrated embodiments of the inventioncan be formed from, for example, doped silica glass and/or polymermaterial. The optical fiber 410 can be cylindrical in shape and isdesigned to guide single-mode optical signals. In the illustratedembodiments of the invention, the cladding (not shown) of the opticalfiber 410 has a diameter that is between approximately 40 to 130 microns(μm), or 80, 90, or 125 μm. The core (not shown) of the optical fiber410 has a diameter between 2 and 15 μm, or between 8 and 11 The opticalfiber 410 is held in proximity to the optical fiber coupler region 412using any of multiple known structures configured and arranged to securethe optical fiber 410 and through the fiber coupler region 412 to theFP-WG 420 (specifically, the FP-WG segment 422A) in an optically alignedmating arrangement. The fiber coupler region 412 is configured inaccordance with aspects of the invention to includes a mode that issimilar to the mode of the optical fiber 410 to provide low-losstransitions from the optical fiber 410 to the optical fiber coupler 412of the FP-WG 420 (specifically, the FP-WG segment 422A).

The FP-WG 420 is shown in simplified form for ease of illustration andexplanation. The FP-WG 420 can include a flexible substrate portion (notshown). The flexible substrate portion can include, for example, apolyimide, polysilane, polynorbornene, polyethylene, epoxy, acrylicresin, or a fluorinated derivative of a resin material. The flexiblesubstrate portion can be substantially transparent for wavelengthsbetween approximately 350 and 400 nm. The flexible substrate portion canbe approximately 15 to 1000 μm thick, 0.1-50 mm wide, and 0.1 to 500 mmlong. The flexible substrate portion can also define the cladding 424 ofthe FP-WG 420.

The core 422 of the FP-WG 420 can be formed using spin-on deposition andphotolithographic methods. The core 422 is substantially transparent tothe optical signals, can be formed from a polymer material, and issurrounded by the cladding portion(s) 424, described in greater detailbelow. The cladding portion 424 is substantially transparent to theoptical signals. The wavelength range of the optical signals transmittedthrough the optical coupling system 400 can be, for example, between 950and 1650 nanometers (nm), or for a 100 or 65 nm wide wavelength spectrumlocated between 950 and 1650 nanometers (nm). The FP-WG 420 is asingle-mode waveguide, and the core 422 is formed from a substantiallytransparent material such as, for example, a polymer material having apropagation loss that is less than 10 dB/cm, or less than approximately2 dB/cm for the wavelength range of the optical signals (350-2500 nm, or800-1650 nm, or 1280-1600 nm, or for a 60 nm wide wavelength spectrum,located between 950 and 1650 nanometers (nm)).

In the illustrated embodiments of the invention, the fiber couplerregion 412 of the FP-WG segment 420A functions as an efficient couplerto optical fibers, segment 420D as a first optical mode converterportion, FP-WG segment 420B functions as a routing portion, segment 420Eas a second optical mode converter portion, and the FP-WG segment 420Cfunctions as an adiabatic coupler to the integrated photonic chip 440.In the illustrated embodiments of the invention, the FP-WG segment 422Ais arranged to provide adequate mode matching for butt-coupling to theoptical fiber 410 while the FP-WG segment 422C is arranged to provideadiabatic coupling to the integrated photonic chip 440.

FIG. 5A depicts a computer-based optical simulation and design (OSD)system configured to a implement a MWC-OLP waveguide design approach inaccordance with aspects of the invention. The OSD system 500 includes amathematical computing & control (MCC) module (or algorithm) 512communicatively coupled to an optical simulator 514. The opticalsimulator 514 can be implemented as a known commercially availablealgorithm running on the computer system 510. The optical simulator 514is configured to simulate the expected optical performance of awaveguide based on the waveguide's design parameters. The MCC module 512can be implemented as a commercially available algorithm running on thecomputer system 510. An example of a suitable known softare program forimplementing the MCC module 512 is a software program known commerciallyas MATLAB® and available from MathWorks® or fimmPROP® by Photon Design®.The MCC module 512 can be used to control the simulator 514 to runmultiple simulations to develop the various optimzation maps 104A, 104B,104C, 104D, 304 (shown in FIGS. 2 and 3B) and the combined-lossoptimization map 700 (shown in FIG. 7) that are used to optimize theworst-case optical-loss performance based on a combination ofparameters/constraints/tolerances 502. The optimization routines used inthe MCC module 512 are blind to the problem that is being solved, andcan be programmed using routine skill in the relevant arts to definewhat is known as an “objective function,” an “error function,” or a“figure-of-merit,” which is just the characteristic that optimizationalgorithms of the MCC module 512 optimizes. In accordance with aspectsof the invention, the figure-of-merit is the worst-case optical-lossperformance within the waveguide's fabrication tolerance window.

FIG. 5B depicts additional details of how the computer system 510 of thecomputer-based OSD system 500 shown in FIG. 5A can be a computer system510A, which can be used to implement any of the computer-basedcomponents of the various embodiments of the invention described herein.The computer system 510A includes an exemplary computing device(“computer”) 520 configured for performing various aspects of thecontent-based semantic monitoring operations described herein inaccordance aspects of the invention. In addition to computer 520,exemplary computer system 510A includes network 534, which connectscomputer 520 to additional systems (not depicted) and can include one ormore wide area networks (WANs) and/or local area networks (LANs) such asthe Internet, intranet(s), and/or wireless communication network(s).Computer 520 and additional system are in communication via network 514,e.g., to communicate data between them.

Exemplary computer 520 includes processor cores 522, main memory(“memory”) 528, and input/output component(s) 530, which are incommunication via bus 532. Processor cores 522 include cache memory(“cache”) 524 and controls 526. Cache 524 can include multiple cachelevels (not depicted) that are on or off-chip from processor 522. Memory528 can include various data stored therein, e.g., instructions,software, routines, etc., which, e.g., can be transferred to/from cache524 by controls 526 for execution by processor 522. Input/outputcomponent(s) 530 can include one or more components that facilitatelocal and/or remote input/output operations to/from computer 520, suchas a display, keyboard, modem, network adapter, etc. (not depicted).

FIG. 6 depicts an example of a method 600 that can be implemented usingthe OSD system 500 (shown in FIG. 5A) to “globally” determine theconfinement parameters of the multi-segmented FP-WG 420 (shown in FIGS.4A and 4B) using the novel MWC-OLP waveguide design approach(represented by the optical-loss plot 300 and the asymmetricoptical-loss curve 302 shown in FIG. 3A) according to embodiments of theinvention, wherein the novel MWC-OLP waveguide design approach definesthe confinement parameters of the FP-WG 420 based at least in part onfabrication tolerances of the FP-WG 420, and wherein the novel MWC-OLPwaveguide design approach further defines the confinement parameters to,collectively, provide a “maximized worst-case optical-loss performancelevel (or a “best” worst-case optical-loss level) of the FP-WG 420within the fabrication tolerances. Turning now to an overview of themethod 600, each waveguide segment 420A, 420B, 420C of the FP-WG 420 isconfigured to incorporate “common” requirements that apply to all of thewaveguide segments 420A, 420B, 420C, along with “unique” requirementsthat apply to (or are based on) unique features or requirements of thatparticular waveguide segment. For example, the fiber coupler region 412of the FP-WG segment 420A has the unique requirement of matching withthe energy distribution (or mode) of the optical fiber 410. The FP-WGsegment 420B does not need to match the energy distribution (or mode) ofthe optical fiber 410 but instead has the unique requirement of havingstrong optical propagation characteristics to accommodate the Sharpebends are present throughout the routing paths of the FP-WG segment420B. The FP-WG segment 420C does not need to match the energydistribution of the optical fiber 410, and does not need to accommodatebends, but instead has the unique requirement of need to effectively andefficiently transfer optical energy to the photonic chip 440. Inembodiments of the invention, all of the waveguide segments 420A, 420B,420C have the common requirement of being robust to changes in waveguideparameters that result from fabrication tolerances of the FP-WG 420. Inembodiments of the invention, all of the waveguide segments 420A, 420B,420C have the common requirement of having parameter constraints thatenable layer-by-layer planar fabrication operations, which can require,for example, that the heights throughout the FP-WG 420 has to besubstantially the same while the width throughout the FP-WG 420 canchange. In embodiments of the invention, all of the waveguide segments420A, 420B, 420C have the common requirement of maximizing theworst-case optical-loss performance of the FP-WG 420.

The method 600 uses the OSD system 500 (shown in FIG. 5A) to generateinitial sets of confinement parameters that take into account the uniquerequirements of each waveguide segment 420A, 420B, 420C. However, theinitial sets of confinement parameters define waveguide cross-sectionsA, B, C that can be effective for one waveguide segment but not another.For example, the initial sets of confinement parameters can definewaveguide cross-sections A and C that are effective for the FP-WGsegment 420A but not very effective for the FP-WG segment 420C.Accordingly, the method 600 uses the OSD system 500 to perform a“global” optimization across the waveguide segments 420A, 420B, 420C bycombining the optical-loss performance from the initial sets ofconfinement parameters and generating “combined-loss” optimzation maps(e.g., map 700 shown in FIG. 7) that map the initial sets of confinementparameters over a large parameter space. The method 600 is configured totake into account various causes of optical loss, including but notlimited to optical propagation loss, measured in decibels per unit ofpropagation length, which is due to waveguide material absorption andimperfections in the patterning of the waveguide core and cladding; bendloss, which is radiation of guided light in waveguide bends; andtransition loss, which is the loss induced by changes in the waveguidecore or cladding cross-section (e.g., abrupt changes and smooth changes,such as adiabatic waveguide tapers). Transition loss can be asignificant source of optical loss when variations in the speed and sizeof optical modes in routing components are notable such as in going fromlarge optical fiber modes (e.g., about 10 microns) to small on-chipwaveguide modes (e.g., about ½ micron). The method 600 uses the OSCsystem 500 to evaluate the combined-loss optimzation maps to identifythe confinement parameters that work well for all of the waveguidesegments 420A, 420B, 420C. As an example, for a cladding height and anindex contrast that are determined for the initial sets of confinementparameters, the combined-loss optimization maps are generated and usedto identify the range of widths that will maximize optical-lossperformance for FP-WG segments 420A, 420B, and 420C within a range offabrication tolerances of the FP-WG 420. More specifically, the method600 optimizes the width for each set of explored combined confinementparameters to achieve a representative total optical-loss at eachconfinement parameter space point.

Turning now to a more detailed description of the method 600, as shownin FIG. 6, the method 600 begins at block 602 by optimizing the opticalfiber coupler region 412 (shown in FIG. 4A) for robustness tofabrication tolerances 303 (shown in FIG. 3) taking into account theconfinement parameters, fabrication constraints, and fabricationtolerances shown in blocks 620, 622, 624, 626. Block 602 is performedfor a map of assumptions on index contrast and the width of the fibercoupler region 412. Because the minimum waveguide width is a constraintin many layer-by-layer planar waveguide fabrication processes,embodiments of the invention are configured to set a width and optimizefor the height, thus providing design clarity for various fabricationcapabilities and setting a map of possible confinement parameters ofcross-section A. Block 604 starts from the map of index contrast andwaveguide heights generated at block 602 and finds the edge of thesingle mode condition with padding for fabrication tolerances, takinginto account the additional confinement parameter requirements of block628. This will provide a map of waveguide widths at cross-section B forthe assumptions on index and height. Block 606 computes bend loss forevery cross-section B of the map generated at block 602 to account forthe optical loss that results from the bends that are needed in theFP-WG waveguide segment 420B for routing. At block 608, starting fromthe map of index contrast and waveguide heights, the waveguide widthcorresponding to the edge of confinement for the fourth mode is foundwith padding for fabrication tolerances (e.e., result is a slightlymultimode waveguide by allowing one additional mode but not two modes ontop of the two modes of single mode operation), and by taking intoaccount the additional confinement parameters of block 630. Thus, block608 sets a corresponding map of cross-section C. Block 610 computes theworst-case optical losses at various abrupt waveguide transitions forthe map of cross-sections C, (scattering at cladding changes near thechip edge and on-chip taper onset). Block 612 computes worst-caseadiabatic crossing loss for the map of cross-sections C. Block 614 addsall losses (fiber coupler loss (cross-section A), bend loss(cross-section B), scattering loss from cladding transitions(cross-section C), adiabatic crossing loss (cross-section C) andpropagation loss (all cross-sections) to generate a map of totalcombined loss, an example of which is shown as the combined optical-lossoptimization map 700 (shown in FIG. 7) for an exemplary subset. Morespecifically, the combined-loss optimization map 700 is a 3D graphs thatshows the worst-case loss along the vertical the y-axis, along with afunction of the index contrast on the x-axis. The various curves on themap 700 represent the effective height of the waveguide 420. The variousdesigns are defined by the choice of fiber coupler width, which in turnprovides the waveguide height throughout. The impact of the choice of astrictly single-mode or slightly multi-mode cross-section 420C is alsoshown. Mode confinement consideration determine the rest of the design.

FIG. 8 depicts a cross-sectional view of the FP-WG 420 shown in FIGS. 4Aand 4B, taken along lines A-A, B-B, or C-C shown in FIG. 4A. The FP-WG420 includes a core 422, a lower cladding 425, and an upper cladding426, configured and arranged as shown. In accordance with aspects of theinvention, a MWC-OLP waveguide design approach (e.g., method 600 shownin FIG. 6) was used to select the confinement parameters h1, n1, h2, n2,h3, w3, Θ3, n3 to maximize a worst-case optical-loss performance of theFP-WG 420 within the waveguide's fabrication tolerance window. Inaccordance with aspects of the invention, the confinement parameters h1,n1, h2, n2, h3, w3, Θ3, n3 appreciate and take into account theasymmetric impact that the confinement parameters h1, n1, h2, n2, h3,w3, Θ3, n3 have on optical-loss performance and worst-case optical-lossperformance in that the confinement parameters h1, n1, h2, n2, h3, w3,Θ3, n3 do not attempt to maximize, and do not consider, the impact thatthe selected and defined confinement parameters h1, n1, h2, n2, h3, w3,Θ3, n3 have on peak optical-loss performance of the FP-WG 420. In someaspects of the invention, the confinement parameters h1, n1, h2, n2, h3,w3, Θ3, n3 are defined based at least in part on fabrication tolerancesof the FP-WG 420, and based at least in part on minimizing the impactthat the fabrication tolerances have on the worst-case optical-lossperformance of the FP-WG 420. Hence, the FP-WG 420 having theconfinement parameters h1, n1, h2, n2, h3, w3, Θ3, n3 in accordance withaspects of the invention are robust to variations in fabricationtolerances in that the novel confinement parameters h1, n1, h2, n2, h3,w3, Θ3, n3 make the FP-WG 420 less susceptible to variations in theworst-case optical-loss performance of the FP-WG 420 over a range ofwaveguide fabrication tolerances.

The novel flexible waveguide confinement parameters h1, n1, h2, n2, h3,w3, Θ3, n3 are further configured to enable the FP-WG 420 to befabricated using known layer-by-layer planar fabrication techniques.More specifically, known layer-by-layer planar fabrication operationsused to fabricate the FP-WG 420 dictate that the FP-WG 420 have asubstantially uniform height (h1 plus h2), cladding refractive index(n1, n2), and core refractive index (n3) throughout the length of theFP-WG 420. Hence, in accordance with aspects of the invention, theheight, cladding refractive index, and core refractive index of theFP-WG 420 are defined to maximize the worst-case optical-lossperformance of the flexible waveguide while also remaining substantiallyuniform throughout the length of the FP-WG 420 to enable thelayer-by-layer planar fabrication operations. Additionally, inaccordance with aspects of the invention, the fabrication constraintsplaced on the confinement parameters h1, n1, h2, n2, h3, w3, Θ3, n3 caninclude fabrication capabilities that limit the set the minimum width ofthe FP-WG 420. Hence, in accordance with aspects of the invention, thewidth w3 of the core 422 is defined to maximize the worst-caseoptical-loss performance of the FP-WG 420 while also maintaining aminimum width w3 dictated by the minimum feature size constraints of therelevant layer-by-layer planar fabrication processes used to form theFP-WG 420.

FIG. 9 depicts a table 900 showing confinement parameters and ranges ofconfinement parameters of the cross-sectional view of the FP-WG 420shown in FIG. 8, taken along line A-A of the FP-WG 420 shown in FIG. 4A,wherein the confinement parameters and ranges of confinement parametersare determined in accordance with the method 600 shown in FIG. 6.

FIG. 10 depicts a table 1000 showing confinement parameters and rangesof confinement parameters of the cross-sectional view of the FP-WG 420shown in FIG. 8, taken along line B-B of the FP-WG shown in FIG. 4A,wherein the confinement parameters and ranges of confinement parametersare determined in accordance with the method 600 shown in FIG. 6.

FIG. 11 depicts a table 1100 showing confinement parameters and rangesof confinement parameters of the cross-sectional view of the FP-WG 420shown in FIG. 8, taken along line C-C of the FP-WG 420 shown in FIG. 4A,wherein the confinement parameters and ranges of confinement parametersare determined in accordance with the method 600 shown in FIG. 6.

Various embodiments of the invention are described herein with referenceto the related drawings. Alternative embodiments of the invention can bedevised without departing from the scope of this invention. Variousconnections and positional relationships (e.g., over, below, adjacent,etc.) are set forth between elements in the following description and inthe drawings. These connections and/or positional relationships, unlessspecified otherwise, can be direct or indirect, and the presentinvention is not intended to be limiting in this respect. Accordingly, acoupling of entities can refer to either a direct or an indirectcoupling, and a positional relationship between entities can be a director indirect positional relationship. Moreover, the various tasks andprocess steps described herein can be incorporated into a morecomprehensive procedure or process having additional steps orfunctionality not described in detail herein.

The terminology used herein is for the purpose of describing particularembodiments only and is not intended to be limiting. As used herein, thesingular forms “a”, “an” and “the” are intended to include the pluralforms as well, unless the context clearly indicates otherwise. It willbe further understood that the terms “comprises,” “comprising,”“includes,” “including,” “has,” “having,” “contains” or “containing,” orany other variation thereof, are intended to cover a non-exclusiveinclusion. For example, a composition, a mixture, process, method,article, or apparatus that comprises a list of elements is notnecessarily limited to only those elements but can include otherelements not expressly listed or inherent to such composition, mixture,process, method, article, or apparatus.

Additionally, the term “exemplary” is used herein to mean “serving as anexample, instance or illustration.” Any embodiment or design describedherein as “exemplary” is not necessarily to be construed as preferred oradvantageous over other embodiments or designs. The terms “at least one”and “one or more” are understood to include any integer number greaterthan or equal to one, i.e. one, two, three, four, etc. The terms “aplurality” are understood to include any integer number greater than orequal to two, i.e. two, three, four, five, etc. The term “connection”can include both an indirect “connection” and a direct “connection.”

The terms “about,” “substantially,” “approximately,” and variationsthereof, are intended to include the degree of error associated withmeasurement of the particular quantity based upon the equipmentavailable at the time of filing the application. For example, “about”can include a range of ±8% or 5%, or 2% of a given value.

The present invention may be a system, a method, and/or a computerprogram product. The computer program product may include a computerreadable storage medium (or media) having computer readable programinstructions thereon for causing a processor to carry out aspects of thepresent invention.

The computer readable storage medium can be a tangible device that canretain and store instructions for use by an instruction executiondevice. The computer readable storage medium may be, for example, but isnot limited to, an electronic storage device, a magnetic storage device,an optical storage device, an electromagnetic storage device, asemiconductor storage device, or any suitable combination of theforegoing. A non-exhaustive list of more specific examples of thecomputer readable storage medium includes the following: a portablecomputer diskette, a hard disk, a random access memory (RAM), aread-only memory (ROM), an erasable programmable read-only memory (EPROMor Flash memory), a static random access memory (SRAM), a portablecompact disc read-only memory (CD-ROM), a digital versatile disk (DVD),a memory stick, a floppy disk, a mechanically encoded device such aspunch-cards or raised structures in a groove having instructionsrecorded thereon, and any suitable combination of the foregoing. Acomputer readable storage medium, as used herein, is not to be construedas being transitory signals per se, such as radio waves or other freelypropagating electromagnetic waves, electromagnetic waves propagatingthrough a waveguide or other transmission media (e.g., light pulsespassing through a fiber-optic cable), or electrical signals transmittedthrough a wire.

Computer readable program instructions described herein can bedownloaded to respective computing/processing devices from a computerreadable storage medium or to an external computer or external storagedevice via a network, for example, the Internet, a local area network, awide area network and/or a wireless network. The network may comprisecopper transmission cables, optical transmission fibers, wirelesstransmission, routers, firewalls, switches, gateway computers and/oredge servers. A network adapter card or network interface in eachcomputing/processing device receives computer readable programinstructions from the network and forwards the computer readable programinstructions for storage in a computer readable storage medium withinthe respective computing/processing device.

Computer readable program instructions for carrying out operations ofthe present invention may be assembler instructions,instruction-set-architecture (ISA) instructions, machine instructions,machine dependent instructions, microcode, firmware instructions,state-setting data, or either source code or object code written in anycombination of one or more programming languages, including an objectoriented programming language such as Smalltalk, C++ or the like, andconventional procedural programming languages, such as the “C”programming language or similar programming languages. The computerreadable program instructions may execute entirely on the user'scomputer, partly on the user's computer, as a stand-alone softwarepackage, partly on the user's computer and partly on a remote computeror entirely on the remote computer or server. In the latter scenario,the remote computer may be connected to the user's computer through anytype of network, including a local area network (LAN) or a wide areanetwork (WAN), or the connection may be made to an external computer(for example, through the Internet using an Internet Service Provider).In some embodiments, electronic circuitry including, for example,programmable logic circuitry, field-programmable gate arrays (FPGA), orprogrammable logic arrays (PLA) may execute the computer readableprogram instructions by utilizing state information of the computerreadable program instructions to personalize the electronic circuitry,in order to perform aspects of the present invention.

Aspects of the present invention are described herein with reference toflowchart illustrations and/or block diagrams of methods, apparatus(systems), and computer program products according to embodiments of theinvention. It will be understood that each block of the flowchartillustrations and/or block diagrams, and combinations of blocks in theflowchart illustrations and/or block diagrams, can be implemented bycomputer readable program instructions.

These computer readable program instructions may be provided to aprocessor of a general purpose computer, special purpose computer, orother programmable data processing apparatus to produce a machine, suchthat the instructions, which execute via the processor of the computeror other programmable data processing apparatus, create means forimplementing the functions/acts specified in the flowchart and/or blockdiagram block or blocks. These computer readable program instructionsmay also be stored in a computer readable storage medium that can directa computer, a programmable data processing apparatus, and/or otherdevices to function in a particular manner, such that the computerreadable storage medium having instructions stored therein comprises anarticle of manufacture including instructions which implement aspects ofthe function/act specified in the flowchart and/or block diagram blockor blocks.

The computer readable program instructions may also be loaded onto acomputer, other programmable data processing apparatus, or other deviceto cause a series of operational steps to be performed on the computer,other programmable apparatus or other device to produce a computerimplemented process, such that the instructions which execute on thecomputer, other programmable apparatus, or other device implement thefunctions/acts specified in the flowchart and/or block diagram block orblocks.

The flowchart and block diagrams in the Figures illustrate thearchitecture, functionality, and operation of possible implementationsof systems, methods, and computer program products according to variousembodiments of the present invention. In this regard, each block in theflowchart or block diagrams may represent a module, segment, or portionof instructions, which comprises one or more executable instructions forimplementing the specified logical function(s). In some alternativeimplementations, the functions noted in the block may occur out of theorder noted in the figures. For example, two blocks shown in successionmay, in fact, be executed substantially concurrently, or the blocks maysometimes be executed in the reverse order, depending upon thefunctionality involved. It will also be noted that each block of theblock diagrams and/or flowchart illustration, and combinations of blocksin the block diagrams and/or flowchart illustration, can be implementedby special purpose hardware-based systems that perform the specifiedfunctions or acts or carry out combinations of special purpose hardwareand computer instructions.

The terminology used herein is for the purpose of describing particularembodiments only and is not intended to be limiting of the presentinvention. As used herein, the singular forms “a”, “an” and “the” areintended to include the plural forms as well, unless the context clearlyindicates otherwise. It will be further understood that the terms“comprises” and/or “comprising,” when used in this specification,specify the presence of stated features, integers, steps, operations,elements, and/or components, but do not preclude the presence oraddition of one or more other features, integers, steps, operations,element components, and/or groups thereof.

The corresponding structures, materials, acts, and equivalents of allmeans or step plus function elements in the claims below are intended toinclude any structure, material, or act for performing the function incombination with other claimed elements as specifically claimed. Thedescription of the present invention has been presented for purposes ofillustration and description, but is not intended to be exhaustive orlimited to the invention in the form described. Many modifications andvariations will be apparent to those of ordinary skill in the artwithout departing from the scope and spirit of the invention. Theembodiment was chosen and described in order to best explain theprinciples of the invention and the practical application, and to enableothers of ordinary skill in the art to understand the invention forvarious embodiments with various modifications as are suited to theparticular use contemplated.

It will be understood that those skilled in the art, both now and in thefuture, may make various improvements and enhancements which fall withinthe scope of the claims which follow.

What is claimed is:
 1. An optical waveguide structure having waveguidedimensions that are within a range of fabrication tolerances, theoptical waveguide structure comprising: a multi-segmented opticalwaveguide comprising: a first waveguide segment comprising a set offirst waveguide segment confinement parameters; a second waveguidesegment communicatively coupled to the first waveguide segment andconfigured to route optical data through a routing path having bends,the second waveguide segment comprising a set of second waveguidesegment confinement parameters; and a third waveguide segmentcommunicatively coupled to the second waveguide segment and comprising aset of third waveguide segment confinement parameters; wherein themulti-segmented optical waveguide is configured to guide optical dataaccording to an asymmetric optical-loss performance curve that issubstantially asymmetrical with respect to a peak optical-lossperformance level of the asymmetric optical-loss performance curve;wherein the asymmetric optical-loss performance curve comprises a plotof: the set of first waveguide segment confinement parameters, the setof second waveguide segment confinement parameters, and the set of thirdwaveguide segment confinement parameters on a first axis; and a level ofoptical-loss performance that results from the set of first waveguidesegment confinement parameters, the set of second waveguide segmentconfinement parameters, and the set of third waveguide segmentconfinement parameters on a second axis; wherein the set of firstwaveguide segment confinement parameters, the set of second waveguidesegment confinement parameters, and the set of third waveguide segmentconfinement parameters are each determined based at least in part on therange of fabrication tolerances; and wherein the set of first waveguidesegment confinement parameters, the set of second waveguide segmentconfinement parameters, and the set of third waveguide segmentconfinement parameters are configured to, collectively, provide theasymmetric optical-loss performance curve with a predeterminedworst-case optical-loss performance level within the range offabrication tolerances.
 2. The structure of claim 1, wherein: themulti-segmented optical waveguide further comprises a multi-segmentedcore and a multi-segmented cladding; the first waveguide segmentcomprises: a first core segment of the multi-segmented core; and a firstcladding segment of the multi-segmented cladding; the second waveguidesegment comprises: a second core segment of the multi-segmented core;and a second cladding segment of the multi-segmented cladding; the thirdwaveguide segment comprises: a third core segment of the multi-segmentedcore; and a third cladding segment of the multi-segmented cladding; thefirst cladding segment comprises a top first cladding segment region anda bottom first cladding segment region; the second cladding segmentcomprises a top second cladding segment region and a bottom secondcladding segment region; and the third cladding segment comprises a topthird cladding segment region and a bottom third cladding segmentregion.
 3. The structure of claim 2, wherein: the first core segmentcomprises a first core segment sidewall that forms a predetermined firstcore segment angle with respect to a first core segment bottom surface;the second core segment comprises a second core segment sidewall thatforms a predetermined second core segment angle with respect to a secondcore segment bottom surface; and the third core segment comprises athird core segment sidewall that forms a predetermined third coresegment angle with respect to a third core segment bottom surface. 4.The structure of claim 3, wherein the set of first core segmentconfinement parameters comprises: a length dimension of the firstwaveguide segment that is greater than or equal to about 1 um; a bottomfirst cladding segment refractive index that is within a range fromabout 1.49 to about 1.54; a first core segment refractive index that iswithin a range from about 1.007 to 1.008 times the bottom first claddingsegment refractive index; a top first cladding segment refractive indexthat is about ±0.0006 of the bottom first cladding segment refractiveindex; the predetermined first core segment angle that is within a rangefrom about 30 degrees to about 150 degrees; a first core segment heightdimension that is within a range from about 2.4 microns to about 4.1microns; a first core segment width dimension that is within a rangefrom about 1.75 microns to about 2.25 microns; a bottom first claddingsegment region height dimension that is within a range from about 5microns to about 5000 microns; and a top first cladding segment regionheight dimension that is within a range from about 5 microns to about5000 microns.
 5. The structure of claim 4, wherein the set of firstwaveguide segment confinement parameters is the same as the set ofsecond waveguide segment confinement parameters except that a range ofsecond core segment width dimensions in the set of second waveguidesegment confinement parameters is different than the range of first coresegment width dimensions.
 6. The structure of claim 5, wherein the rangeof second core segment width dimensions comprises from about 4.0 micronsto about 5.1 microns.
 7. The structure of claim 5, wherein the range ofsecond core segment width dimensions comprises from about 4.2 microns toabout 5.1 microns.
 8. The structure of claim 4, wherein the set of firstwaveguide segment confinement parameters is the same as the set of thirdwaveguide segment confinement parameters except that: a range of thirdcore segment width dimensions in the set of third waveguide segmentconfinement parameters is different than the range of first core segmentwidth dimension; and a range of top third cladding segment regionrefractive indices in the set of third waveguide segment confinementparameters is different than the range of top first cladding segmentregion refractive indices.
 9. The structure of claim 8, wherein therange of first core segment width dimensions comprises from about 1.75microns to about 2.25 microns.
 10. The structure of claim 9, wherein therange of third core segment width dimensions comprises from about 5.7microns to about 8.4 microns.
 11. The structure of claim 10, wherein therange of top first cladding segment region refractive indices comprisesfrom a minimum refractive index of the bottom first cladding region±0.0006 to a maximum refractive index of the bottom first claddingregion ±0.0006.
 12. The structure of claim 11, wherein the range of topthird cladding segment region refractive indices comprises from theminimum refractive index of the bottom first cladding region minus 0.001to the maximum refractive index of the bottom first cladding regionmultiplied by about 1.008.
 13. The structure of claim 12, wherein theminimum refractive index of the bottom first cladding region comprisesabout 1.49.
 14. The structure of claim 13, wherein the maximumrefractive index of the bottom first cladding region comprises about1.54.
 15. The structure of claim 19, wherein the range of first coresegment width dimensions comprises from about 1.75 microns to about 2.25microns.
 16. The structure of claim 15, wherein the range of third coresegment width dimensions comprises from about 6.6 microns to about 7.9microns.
 17. The structure of claim 16, wherein the range of top firstcladding segment region refractive indices comprises from a minimumrefractive index of the bottom first cladding region ±0.0006 to amaximum refractive index of the bottom first cladding region ±0.0006.18. The structure of claim 17, wherein the range of top third claddingsegment region refractive indices comprises from the minimum refractiveindex of the bottom first cladding region minus 0.001 to a maximumrefractive index of a third core segment.
 19. The structure of claim 18,wherein the minimum refractive index of the bottom first cladding regioncomprises about 1.50.
 20. The structure of claim 19, wherein the maximumrefractive index of the bottom first cladding region comprises about1.52.